參考文獻 |
[1] A. Midilli, M. Ay, I. Dincer, M. A. Rosen, “On hydrogen and hydrogen energy strategies I: current status and needs”, Renewable and Sustainable Energy Reviews, 9, 255-271 (2005).
[2] M. S. Dresselhaus, I. L. Thomas, “Alternative energy technologies”, Nature, 414, 332-337 (2001).
[3] G. J. Stiegel, M. Ramezan, “Hydrogen from coal gasification: An economical pathway to a sustainable energy future” International Journal of Coal Geology, 65, 173-190 (2006).
[4] M. H. Shedid, S. Elshokary, “Hydrogen Production from an Alkali Electrolyzer Operating with Egypt Natural Resources”, Smart Grid and Renewable Energy, 06 (01), 12.
[5] D. R. Palo, R. A. Dagle, J. D. Holladay, “Methanol steam reforming for hydrogen production”, Chemical Reviews, 107, 3992-4021 (2007).
[6] X. X. Zou, Y. Zhang, “Noble metal-free hydrogen evolution catalysts for water splitting”, Chemical Society Reviews, 44, 5148-5180 (2015).
[7] A. Paracchino, V. Laporte, K. Sivula, M. Gratzel, E. Thimsen, “Highly active oxide photocathode for photoelectrochemical water reduction”, Nature Materials, 10, 456-461 (2011).
[8] Y. H. Hung, C. Y. Su, “Highly efficient electrocatalytic hydrogen production via MoSx/3D-graphene as hybrid electrode”, International Journal of Hydrogen Energy, 42, 22091-22099 (2017).
[9] L. B. Wu, L. Yu, X. Xiao, F. H. Zhang, S. W. Song, S. Chen, Z. F. Ren, “Recent Advances in Self-Supported Layered Double Hydroxides for Oxygen Evolution Reaction”, Research, 2020, 3976278-3976278 (2020).
[10] M. K. Min, J. H. Cho, K. W. Cho, H. Kim, “Particle size and alloying effects of Pt-based alloy catalysts for fuel cell applications”, Electrochimica Acta, 45, 4211-4217 (2000).
[11] Y. Lee, J. Suntivich, K. J. May, E. E. Perry, Y. Shao-Horn, “Synthesis and Activities of Rutile IrO2 and RuO2 Nanoparticles for Oxygen Evolution in Acid and Alkaline Solutions”, The Journal of Physical Chemistry Letters, 3, 399-404 (2012).
[12] Q. Yuan, Z. Y. Zhou, J. Zhuang, X. Wang, Pd-Pt random alloy nanocubes with tunable compositions and their enhanced electrocatalytic activities”, Chemical Communications, 46, 1491-1493 (2010).
[13] X. L. Yang, A. Y. Lu, Y. Zhu, S. X. Min, M. N. Hedhili, Y. Han, K. W. Huang, L. J. Li, “Rugae-like FeP nanocrystal assembly on a carbon cloth: an exceptionally efficient and stable cathode for hydrogen evolution”, Nanoscale, 7, 10974-10981 (2015).
[14] C. J. Tseng, C. H. Wang, K. W. Cheng, “Photoelectrochemical performance of gallium-doped AgInS2 photoelectrodes prepared by electrodeposition process”, Solar Energy Materials and Solar Cells, 96, 33-42 (2012).
[15] K. R. Lee, Y. P. Hsu, J. K. Chang, S. W. Lee, C. J. Tseng, J. S. C. Jang, “Effects of Spin Speed on the Photoelectrochemical Properties of Fe2O3 Thin Films”, International Journal of Electrochemical Science, 9, 7680-7692 (2014).
[16] A. L. Wang, H. Xu, G. R. Li, “NiCoFe Layered Triple Hydroxides with Porous Structures as High-Performance Electrocatalysts for Overall Water Splitting”, ACS Energy Letters, 1, 445-453 (2016).
[17] Q. S. Liang, K. K. Huang, X. F. Wu, X. Y. Wang, W. Ma, S. H. Feng, “Composition-controlled synthesis of Ni2-xCoxP nanocrystals as bifunctional catalysts for water splitting”, RSC Advances, 7, 7906-7913 (2017).
[18] E. Skulason, G. S. Karlberg, J. Rossmeisl, T. Bligaard, J. Greeley, H. Jonsson, J. K. Norskov, “Density functional theory calculations for the hydrogen evolution reaction in an electrochemical double layer on the Pt(111) electrode”, Physical Chemistry Chemical Physics, 9, 3241-3250 (2007).
[19] W. Li, G. H. Liu, J. D. Li, Y. J. Wang, L. Ricardez-Sandoval, Y. G. Zhang, Z. S. Zhang, “Hydrogen evolution reaction mechanism on 2H-MoS2 electrocatalyst”, Applied Surface Science, 498, 143869 (2019).
[20] R. Moca, "Novel Inorganic materials for hydrogen evolution reaction in electrochemical water splitting", Ph.D., Thesis, University of Glasgow, Scotland, United Kingdom (2019).
[21] J. M. Wei, M. Zhou, A. C. Long, Y. M. Xue, H. B. Liao, C. Wei, Z. C. J. Xu, “Heterostructured Electrocatalysts for Hydrogen Evolution Reaction Under Alkaline Conditions”, Nano-Micro Letters, 10, 75 (2018).
[22] C. G. Morales-Guio, L. A. Stern, X. Hu, “Nanostructured hydrotreating catalysts for electrochemical hydrogen evolution”, Chemical Society Reviews, 43, 6555-6569 (2014).
[23] I. Chorkendorff, J. W. Niemantsverdriet, “Concepts of modern catalysis and kinetics”, Wiley-VCH, Weinheim, pp. 1- 452 (2003).
[24] N. M. Markovic, P. N. Ross, “Surface science studies of model fuel cell electrocatalysts”, Surface Science Reports, 45, 121-229 (2002).
[25] J. D. Benck, T. R. Hellstern, J. Kibsgaard, P. Chakthranont, T. F. Jaramillo, “Catalyzing the Hydrogen Evolution Reaction (HER) with Molybdenum Sulfide Nanomaterials”, ACS Catalysis, 4, 3957-3971 (2014).
[26] J. O. M. Bockris, E. C. Potter, “The Mechanism of the Cathodic Hydrogen Evolution Reaction”, Journal of The Electrochemical Society, 99, 169 (1952).
[27] A. J. Bard, L. R. Faulkner, “Electrochemical methods : fundamentals and applications”, Wiley, New York, 2nd edition, pp. 1-833 (2001).
[28] E. Gileadi, “Physical electrochemistry : fundamentals, techniques and applications”, WILEY-VCH, Weinheim, pp 1-373 (2011).
[29] F. M. Sapountzi, J. M. Gracia, C. J. Weststrate, H. O. A. Fredriksson, J. W. Niemantsverdriet, “Electrocatalysts for the generation of hydrogen, oxygen and synthesis gas”, Progress in Energy and Combustion Science, 58, 1-35 (2017).
[30] S. Shiva Kumar, V. Himabindu, “Hydrogen production by PEM water electrolysis – A review”, Materials Science for Energy Technologies, 2, 442-454 (2019).
[31] J. Zhu, Z. C. Wang, H. Dai, Q. Wang, R. Yang, H. Yu, M. Liao, J. Zhang, W. Chen, Z. Wei, N. Li, L. Du, D. Shi, W. Wang, L. Zhang, Y. Jiang, G. Zhang, “Boundary activated hydrogen evolution reaction on monolayer MoS2”, Nature Communications, 10, 1348 (2019).
[32] J. D. Benck, T. R. Hellstern, J. Kibsgaard, P. Chakthranont, T. F. Jaramillo, “Catalyzing the Hydrogen Evolution Reaction (HER) with Molybdenum Sulfide Nanomaterials”, ACS Catalysis, 4, 3957-3971 (2014).
[33] Y. Yan, B. Y. Xia, Z. C. Xu, X. Wang, “Recent Development of Molybdenum Sulfides as Advanced Electrocatalysts for Hydrogen Evolution Reaction”, ACS Catalysis, 4, 1693-1705 (2014).
[34] P. Liu, J. Li, Y. Lu, B. Xiang, “Facile synthesis of NiS2 nanowires and its efficient electrocatalytic performance for hydrogen evolution reaction”, International Journal of Hydrogen Energy, 43, 72-77 (2018).
[35] J. Y. Zhang, Y. C. Liu, C. Q. Sun, P. X. Xi, S. L. Peng, D. Q. Gao, D. S. Xue, “Accelerated Hydrogen Evolution Reaction in CoS2 by Transition-Metal Doping”, ACS Energy Letters, 3, 779-786 (2018).
[36] J. Y. Zhang, W. Xiao, P. X. Xi, S. B. Xi, Y. H. Du, D. Q. Gao, J. Ding, “Activating and Optimizing Activity of CoS2 for Hydrogen Evolution Reaction through the Synergic Effect of N Dopants and S Vacancies”, ACS Energy Letters, 2, 1022-1028 (2017).
[37] T. T. Wang, D. Q. Gao, W. Xiao, P. X. Xi, D. S. Xue, J. Wang, “Transition-metal-doped NiSe2 nanosheets towards efficient hydrogen evolution reactions”, Nano Research, 11, 6051-6061 (2018).
[38] X. Zhang, J. Ji, Q. Yang, L. Zhao, Q. Yuan, Y. Hao, P. Jin, L. Feng, “Phosphate Doped Ultrathin FeP Nanosheets as Efficient Electrocatalysts for the Hydrogen Evolution Reaction in Acid Media”, ChemCatChem, 11, 2484-2489 (2019).
[39] T. Liu, P. Li, N. Yao, G. Cheng, S. Chen, W. Luo, Y. Yin, “CoP-Doped MOF-Based Electrocatalyst for pH-Universal Hydrogen Evolution Reaction”, Angewandte Chemie International Edition, 131, 4727-4732 (2019).
[40] J. Kibsgaard, T. F. Jaramillo, “Molybdenum Phosphosulfide: An Active, Acid-Stable, Earth-Abundant Catalyst for the Hydrogen Evolution Reaction”, Angewandte Chemie International Edition, 53, 14433-14437 (2014).
[41] E. J. Popczun, J. R. McKone, C. G. Read, A. J. Biacchi, A. M. Wiltrout, N. S. Lewis, R. E. Schaak, “Nanostructured Nickel Phosphide as an Electrocatalyst for the Hydrogen Evolution Reaction” Journal of the American Chemical Society, 135, 9267-9270 (2013).
[42] P. V. Sarma, C. S. Tiwary, S. Radhakrishnan, P. M. Ajayan, M. M. Shaijumon, “Oxygen incorporated WS2 nanoclusters with superior electrocatalytic properties for hydrogen evolution reaction”, Nanoscale, 10, 9516-9524 (2018).
[43] W. F. Chen, C. H. Wang, K. Sasaki, N. Marinkovic, W. Xu, J. T. Muckerman, Y. Zhu, R. R. Adzic, “Highly active and durable nanostructured molybdenum carbide electrocatalysts for hydrogen production”, Energy & Environmental Science, 6, 943-951 (2013).
[44] T. Ishii, K. Yamada, N. Osuga, Y. Imashiro, J.I. Ozaki, “Single-Step Synthesis of W2C Nanoparticle-Dispersed Carbon Electrocatalysts for Hydrogen Evolution Reactions Utilizing Phosphate Groups on Carbon Edge Sites”, ACS Omega, 1, 689-695 (2016).
[45] T. F. Jaramillo, K. P. Jorgensen, J. Bonde, J. H. Nielsen, S. Horch, I. Chorkendorff, “Identification of active edge sites for electrochemical H2 evolution from MoS2 nanocatalysts”, Science, 317, 100-102 (2007).
[46] Y. H. Hung A. Y. Lu, Y. H. Chang, J. K. Huang, J. K. Chang, L. J. Li, C. Y. Su, “Scalable Patterning of MoS2 Nanoribbons by Micromolding in Capillaries”, ACS Applied Materials & Interfaces, 8, 20993-21001 (2016).
[47] J. D. Benck, Z. Chen, L. Y. Kuritzky, A. J. Forman, T. F. Jaramillo, “Amorphous Molybdenum Sulfide Catalysts for Electrochemical Hydrogen Production: Insights into the Origin of their Catalytic Activity”, ACS Catalysis, 2, 1916-1923 (2012).
[48] Y. Yan, B. Xia, X. Ge, Z. Liu, J.-Y. Wang, X. Wang, “Ultrathin MoS2 Nanoplates with Rich Active Sites as Highly Efficient Catalyst for Hydrogen Evolution”, ACS Applied Materials & Interfaces, 5, 12794-12798 (2013).
[49] D. Merki, S. Fierro, H. Vrubel, X. Hu, “Amorphous molybdenum sulfide films as catalysts for electrochemical hydrogen production in water”, Chemical Science, 2, 1262-1267 (2011).
[50] X. R. Gan, L. Y. S. Lee, K. Y. Wong, T. W. Lo, K. H. Ho, D. Y. Lei, H. M. Zhao, “2H/1T Phase Transition of Multilayer MoS2 by Electrochemical Incorporation of S Vacancies”, ACS Applied Energy Materials, 1, 4754-4765 (2018).
[51] D. Z. Wang, X. Y. Zhang, S. Y. Bao, Z. T. Zhang, H. Fei, Z. Z. Wu, “Phase engineering of a multiphasic 1T/2H MoS2 catalyst for highly efficient hydrogen evolution”, Journal of Materials Chemistry A, 5, 2681-2688 (2017).
[52] H. F. Dong, C. H. Liu, H. T. Ye, L. P. Hu, B. S. Fugetsu, W. H. Dai, Y. Cao, X. Q. Qi, H. T. Lu, X. J. Zhang, “Three-dimensional Nitrogen-Doped Graphene Supported Molybdenum Disulfide Nanoparticles as an Advanced Catalyst for Hydrogen Evolution Reaction”, Scientific Reports, 5, (2015).
[53] R. Raccichini, A. Varzi, S. Passerini, B. Scrosati, “The role of graphene for electrochemical energy storage”, Nature Materials, 14, 271-279 (2015)..
[54] K. Yuan, S. Sfaelou, M. Qiu, D. Lützenkirchen-Hecht, X. Zhuang, Y. Chen, C. Yuan, X. Feng, U. Scherf, “Synergetic Contribution of Boron and Fe-Nx Species in Porous Carbons toward Efficient Electrocatalysts for Oxygen Reduction Reaction”, ACS Energy Letters, 3, 252-260 (2018).
[55] Y. H. Hung, D. Dutta, C. J. Tseng, J. K. Chang, A. J. Bhattacharyya, C. Y. Su, “Manipulation of Heteroatom Substitution on Nitrogen and Phosphorus Co-Doped Graphene as a High Active Catalyst for Hydrogen Evolution Reaction”, The Journal of Physical Chemistry C, 123, 22202-22211 (2019).
[56] G. Y. Li, Z. H. Li, X. Xiao, Y. L. An, W. Wang, Z. Q. Hu, “An ultrahigh electron-donating quaternary-N-doped reduced graphene oxide@carbon nanotube framework: a covalently coupled catalyst support for enzymatic bioelectrodes”, J. Mater. Chem. A, 7, 11077-11085 (2019).
[57] S. K. Park, D. Y. Chung, D. Ko, Y. E. Sung, Y. Piao, “Three-dimensional carbon foam/N-doped graphene@MoS2 hybrid nanostructures as effective electrocatalysts for the hydrogen evolution reaction”, Journal of Materials Chemistry A, 4, 12720-12725 (2016).
[58] Y. J. Tang, Y. Wang, X. L. Wang, S. L. Li, W. Huang, L. Z. Dong, C. H. Liu, Y. F. Li, Y. Q. Lan, “Molybdenum Disulfide/Nitrogen-Doped Reduced Graphene Oxide Nanocomposite with Enlarged Interlayer Spacing for Electrocatalytic Hydrogen Evolution”, Advanced Energy Materials, 6, 1600116 (2016).
[59] F. C. Yang, M. J. Kim, M. Brown, B. J. Wiley, “Alkaline Water Electrolysis at 25 A cm-2 with a Microfibrous Flow-through Electrode”, Advanced Energy Materials, 10, 2001174 (2020).
[60] Q. F. Liu, E. D. Wang, G. Q. Sun, “Layered transition-metal hydroxides for alkaline hydrogen evolution reaction”, Chinese Journal of Catalysis, 41, 574-591 (2020).
[61] S. Si, H. S. Hu, R. J. Liu, Z. X. Xu, C. B. Wang, Y. Y. Feng, “Co-NiFe layered double hydroxide nanosheets as an efficient electrocatalyst for the electrochemical evolution of oxygen” International Journal of Hydrogen Energy, 45, 9368-9379 (2020).
[62] X. L. Ma, X. M. Li, A. D. Jagadale, X. G. Hao, A. Abudula, G. Q. Guan, “Fabrication of Cu(OH)2@NiFe-layered double hydroxide catalyst array for electrochemical water splitting”, International Journal of Hydrogen Energy, 41, 14553-14561 (2016).
[63] Y. L. Zhu, Q. Lin, Y. J. Zhong, H. A. Tahini, Z. P. Shao, H. T. Wang, “Metal oxide-based materials as an emerging family of hydrogen evolution electrocatalysts”, Energy & Environmental Science ,13, 3361-3392 (2020).
[64] L. H. Zhang, Q. Fan, K. Li, S. Zhang, X. B. Ma, “First-row transition metal oxide oxygen evolution electrocatalysts: regulation strategies and mechanistic understandings”, Sustainable Energy & Fuels, 4, 5417-5432 (2020).
[65] C. L. Hu, L. Zhang, J. L. Gong, “Recent progress made in the mechanism comprehension and design of electrocatalysts for alkaline water splitting”, Energy & Environmental Science, 12, 2620-2645 (2019).
[66] Y. Q. Wang, J. T. Zhang, “Structural engineering of transition metal-based nanostructured electrocatalysts for efficient water splitting”, Frontiers of Chemical Science and Engineering, 12, 838-854 (2018).
[67] J. Mahmood, F. Li, S. M. Jung, M. S. Okyay, I. Ahmad, S. J. Kim, N. Park, H. Y. Jeong, J. B. Baek, “An efficient and pH-universal ruthenium-based catalyst for the hydrogen evolution reaction”, Nature Nanotechnology, 12, 441-446 (2017).
[68] B. C. Zheng, L. Ma, B. Li, D. Chen, X. L. Li, J. B. He, J. H. Xie, M. Robert, T. C. Lau, “pH universal Ru@N-doped carbon catalyst for efficient and fast hydrogen evolution”, Catalysis Science & Technology, 10, 4405-4411 (2020).
[69] J. Q. Zhao, Z. X. Lu, X. He, X. F. Zhang, Q. Y. Li, T. Xia, W. Zhang, C. H. Lu, “Fabrication and Characterization of Highly Porous Fe(OH)3@Cellulose Hybrid Fibers for Effective Removal of Congo Red from Contaminated Water”, ACS Sustainable Chemisty & Engineering, 5, 7723-7732 (2017).
[70] M. Gong, D. Y. Wang, C. C. Chen, B. J. Hwang, H. J. Dai, “A mini review on nickel-based electrocatalysts for alkaline hydrogen evolution reaction”, Nano Research, 9, 28-46 (2016).
[71] Z. Qiu, C. W. Tai, G. A. Niklasson, T. Edvinsson, “Direct observation of active catalyst surface phases and the effect of dynamic self-optimization in NiFe-layered double hydroxides for alkaline water splitting”, Energy & Environmental Science, 12, 572-581 (2019).
[72] J. X. Guo, J. K. Sun, Y. F. Sun, Q. Y. Liu, X. Zhang, “Electrodepositing Pd on NiFe layered double hydroxide for improved water electrolysis”, Materials Chemistry Frontiers, 3, 842-850 (2019).
[73] Y. Wang, P. Zheng, M. X. Li, Y. R. Li, X. Zhang, J. Chen, X. Fang, Y. J. Liu, X. L. Yuan, X. P. Dai, H. Wang, “Interfacial synergy between dispersed Ru sub-nanoclusters and porous NiFe layered double hydroxide on accelerated overall water splitting by intermediate modulation”, Nanoscale, 12, 9669-9679 (2020).
[74] R. Subbaraman, D. Tripkovic, K. C. Chang, D. Strmcnik, A. P. Paulikas, P. Hirunsit, M. Chan, J. Greeley, V. Stamenkovic, N. M. Markovic, “Trends in activity for the water electrolyser reactions on 3d M(Ni,Co,Fe,Mn) hydr(oxy)oxide catalysts”, Nature Materials, 11, 550-557 (2012).
[75] X. H. Sun, Q. Shao, Y. C. Pi, J. Guo, X. Q. Huang, “A general approach to synthesise ultrathin NiM (M = Fe, Co, Mn) hydroxide nanosheets as high-performance low-cost electrocatalysts for overall water splitting”, Journal of Materials Chemistry A, 5, 7769-7775 (2017).
[76] Y. H. Tang, Q. Liu, L. Dong, H. B. Wu, X. Y. Yu, “Activating the hydrogen evolution and overall water splitting performance of NiFe LDH by cation doping and plasma reduction”, Applied Catalalysis B-Environmental, 266, 118627 (2020).
[77] H. J. Yan, Y. Xie, A. P. Wu, Z. C. Cai, L. Wang, C. G. Tian, X. M. Zhang, H. G. Fu, “Anion-Modulated HER and OER Activities of 3D Ni-V-Based Interstitial Compound Heterojunctions for High-Efficiency and Stable Overall Water Splitting”, Advanced Materials, 31, 1901174 (2019).
[78] U. Costantino, F. Marmottini, M. Nocchetti, R. Vivani, “New synthetic routes to hydrotalcite-like compounds - Characterisation and properties of the obtained materials”, European Journal of Inorganic Chemistry, 1439-1446 (1998).
[79] M. Mališová, M. Horňáček, J. Mikulec, P. Hudec, V. Jorík, “FTIR study of hydrotalcite”, Acta Chimica Slovaca, 11, 147-156 (2018).
[80] C. Arruda, P. H. L. Cardoso, I. M. M. Dias, R. Salomão, “Hydrotalcite Mg6Al2(OH)16(CO3)·4H2O: A potentially useful raw material for refractories”, InterCeram: International Ceramic Review, 62, 187-191 (2013).
[81] Y. Arishige, D. Kubo, K. Tadanaga, A. Hayashi, M. Tatsumisago, “Electrochemical oxygen separation using hydroxide ion conductive layered double hydroxides”, Solid State Ionics, 262, 238-240 (2014).
[82] J. S. Valente, J. Hernandez-Cortez, M. S. Cantu, G. Ferrat, E. Lopez-Salinas, “Calcined layered double hydroxides Mg-Me-Al (Me: Cu, Fe, Ni, Zn) as bifunctional catalysts”, Catalysis Today, 150, 340-345 (2010).
[83] K. Kannimuthu, K. Sangeetha, S. Sam Sankar, A. Karmakar, R. Madhu, S. Kundu, “Investigation on nanostructured Cu-based electrocatalysts for improvising water splitting: a review”, Inorganic Chemistry Frontiers, 8, 234-272 (2021).
[84] A. Jaiswal, R. K. Guautam, M. C. Chattopadhyaya, "Layered Double Hydroxides and the Environment: An Overview” in “Advanced Materials for Agriculture, Food, and Environmental Safety”, Editor: A. Tiwari and S. Mikael, WILEY Scrivener Publishing LLC, Canada, chap. 1, pp. 1-26, 2014.
[85] E. Uzunova, D. Klissurski, S. Kassabov, “Nickel-Iron Hydroxide Carbonate Precursors in the Synthesis of High-Dispersity Oxides”, Journal of Materials Chemistry, 4, 153-159 (1994).
[86] T. S. K. Sharma, K. Y. Hwa, “Rational design and preparation of copper vanadate anchored on sulfur doped reduced graphene oxide nanocomposite for electrochemical sensing of antiandrogen drug nilutamide using flexible electrodes”, Journal of Hazardous Materials, 124659 (2020).
[87] J. Liu, J. S. Wang, B. Zhang, Y. J. Ruan, L. Lv, X. Ji, K. Xu, L. Miao, J. J. Jiang, “Hierarchical NiCo2S4@NiFe LDH Heterostructures Supported on Nickel Foam for Enhanced Overall-Water-Splitting Activity”, ACS Applied Materials & Interfaces 9, 15364-15372 (2017).
[88] M. Bhavanari, K. R. Lee, B. J. Su, D. Dutta, Y. H. Hung, C. J. Tseng, C. Y. Su, “MoSx on Nitrogen-Doped Graphene for High-Efficiency Hydrogen Evolution Reaction: Unraveling the Mechanisms of Unique Interfacial Bonding for Efficient Charge Transport and Stability”, ACS Applied Materials & Interfaces, 12, 34825-34836 (2020).
[89] J. S. Luo, J. H. Im, M. T. Mayer, M. Schreier, M. K. Nazeeruddin, N. G. Park, S. D. Tilley, H. J. Fan, M. Gratzel, “Water photolysis at 12.3% efficiency via perovskite photovoltaics and Earth-abundant catalysts”, Science, 345, 1593-1596 (2014).
[90] S. Anantharaj, K. Karthick, M. Venkatesh, T. V. S. V. Simha, A. S. Salunke, L. Ma, H. Liang, S. Kundu, “Enhancing electrocatalytic total water splitting at few layer Pt-NiFe layered double hydroxide interfaces”, Nano Energy, 39, 30-43 (2017).
[91] C. Y. Su, Y. Xu, W. Zhang, J. Zhao, X. Tang, C. H. Tsai, L. J. Li, “Electrical and Spectroscopic Characterizations of Ultra-Large Reduced Graphene Oxide Monolayers”, Chemistry of Materials, 21, 5674-5680 (2009).
[92] X. Wu, Y. L. Du, X. An, X. M. Xie, “Fabrication of NiFe layered double hydroxides using urea hydrolysis-Control of interlayer anion and investigation on their catalytic performance”, Catalysis Communications, 50, 44-48 (2014).
[93] D. H. Guo, R. Shibuya, C. Akiba, S. Saji, T. Kondo, J. Nakamura, “Active sites of nitrogen-doped carbon materials for oxygen reduction reaction clarified using model catalysts”, Science, 351, 361 (2016).
[94] Y. Xu, Y. P. Mo, J. Tian, P. Wang, H. G. Yu, J. G. Yu, “The synergistic effect of graphitic N and pyrrolic N for the enhanced photocatalytic performance of nitrogen-doped graphene/TiO2 nanocomposites”, Applied Catalalysis B, 181, 810-817 (2016).
[95] X. F. Li, K. Y. Lian, L. Liu, Y. Wu, Q. Qiu, J. Jiang, M. Deng, Y. Luo, “Unraveling the formation mechanism of graphitic nitrogen-doping in thermally treated graphene with ammonia”, Scientific Reports, 6, 23495 (2016).
[96] X. W. Wang, G. Z. Sun, P. Routh, D. H. Kim, W. Huang, P. Chen, “Heteroatom-doped graphene materials: syntheses, properties and applications”, Chemical Society Reviews, 43, 7067-7098 (2014).
[97] A. Y. Lu, X. L. Yang, C. C. Tseng, S. X. Min, S. H. Lin, C. L. Hsu, H. N. Li, H. C. Idriss, J. L. Kuo, K. W. Huang, L. J. Li, “High-Sulfur-Vacancy Amorphous Molybdenum Sulfide as a High Current Electrocatalyst in Hydrogen Evolution”, Small, 12, 5530-5537 (2016).
[98] L. Zhang, L. Ji, P. A. Glans, Y. Zhang, J. Zhu, J. Guo, “Electronic structure and chemical bonding of a graphene oxide-sulfur nanocomposite for use in superior performance lithium-sulfur cells”, Physical Chemistry Chemical Physics, 14, 13670-13675 (2012).
[99] M. C. Meng, H. J. Yan, Y. Q. Jiao, A. P. Wu, X. M. Zhang, R. H. Wang, C. G. Tian, “A 1-methylimidazole-fixation route to anchor small-sized nitrides on carbon supports as non-Pt catalysts for the hydrogen evolution reaction”, RSC Advances, 6, 29303-29307 (2016).
[100] D. O. Scanlon, G. W. Watson, D. J. Payne, G. R. Atkinson, R. G. Egdell, D. S. L. Law, “Theoretical and Experimental Study of the Electronic Structures of MoO3 and MoO2”, The Journal of Physical Chemistry C, 114, 4636-4645 (2010).
[101] K. Inzani, M. Nematollahi, S. M. Selbach, T. Grande, F. Vullum-Bruer, “Progression of reduction of MoO3 observed in powders and solution-processed films”, Thin Solid Films, 626, 94-103 (2017).
[102] Y. Tong, P. Chen, T. Zhou, K. Xu, W. Chu, C. Wu, Y. Xie, “A Bifunctional Hybrid Electrocatalyst for Oxygen Reduction and Evolution: Cobalt Oxide Nanoparticles Strongly Coupled to B,N-Decorated Graphene”, Angewandte Chemie International Edition, 56, 7121-7125 (2017).
[103] D. Usachov, O. Vilkov, A. Grüneis, D. Haberer, A. Fedorov, V. K. Adamchuk, A. B. Preobrajenski, P. Dudin, A. Barinov, M. Oehzelt, C. Laubschat, D. V. Vyalikh, “Nitrogen-Doped Graphene: Efficient Growth, Structure, and Electronic Properties”, Nano Letters, 11, 5401-5407 (2011).
[104] R. Kapoor, S. T. Oyama, B. Frühberger, J. G. Chen, “NEXAFS Characterization and Reactivity Studies of Bimetallic Vanadium Molybdenum Oxynitride Hydrotreating Catalysts”, The Journal of Physical Chemistry B, 101, 1543-1547 (1997).
[105] J. Purans, A. Kuzmin, P. Parent, C. Laffon, “X-ray absorption study of the electronic structure of tungsten and molybdenum oxides on the O K-edge”, Electrochimica Acta, 46, 1973-1976 (2001).
[106] E. J. Yoo, Y. Qiao, H. S. Zhou, “Understanding the effect of the concentration of LiNO3 salt in Li–O2 batteries”, Journal of Materials Chemistry A, 7, 18318-18323 (2019).
[107] J. Y. Hong, W. E. Gent, P. H. Xiao, K. Lim, D. H. Seo, J. P. Wu, P. M. Csernica, C. J. Takacs, D. Nordlund, C. J. Sun, K. H. Stone, D. Passarello, W. L. Yang, D. Prendergast, G. Ceder, M. F. Toney, W. C. Chueh, “Metal-oxygen decoordination stabilizes anion redox in Li-rich oxides”, Nature Materials, 18, 256-265 (2019).
[108] H. K. Jeong, H. J. Noh, J. Y. Kim, M. H. Jin, C. Y. Park, Y. H. Lee X-ray absorption spectroscopy of graphite oxide”, Europhysics Letters, 82, 67004 (2008).
[109] J. T. Francis, A. P. Hitchcock, “Inner-shell spectroscopy of p-benzoquinone, hydroquinone, and phenol: distinguishing quinoid and benzenoid structures”, The Journal of Physical Chemistry, 96, 6598-6610 (1992).
[110] J. A. Rodriguez, J. Dvorak, T. Jirsak“Chemistry of SO2, H2S, and CH3SH on Carbide-Modified Mo(110) and Mo2C Powders: Photoemission and XANES Studies”, The Journal of Physical Chemistry B, 104, 11515-11521 (2000).
[111] K. S. Kim, P. Y. Zhu, N. Li, X. L. Ma, Y. S. Chen, “Characterization of oxygen containing functional groups on carbon materials with oxygen K-edge X-ray absorption near edge structure spectroscopy”, Carbon, 49, 1745-1751 (2011).
[112] S. F. Wu, W. X. Wang, M. C. Li, L. J. Cao, F. C. Lyu, M. Y. Yang, Z. Y. Wang, Y. Shi, B. Nan, S. C. Yu, Z. F. Sun, Y. Liu, Z. G. Lu, “Highly durable organic electrode for sodium-ion batteries via a stabilized α-C radical intermediate”, Nature Communications, 7, 13318 (2016).
[113] B. Debret, M. Andreani, A. Delacour, S. Rouméjon, N. Trcera, H. Williams, “Assessing sulfur redox state and distribution in abyssal serpentinites using XANES spectroscopy”, Earth and Planetary Science Letters, 466, 1-11 (2017).
[114] A. M. El-Sawy, I. M. Mosa, D. Su, C. J. Guild, S. Khalid, R. Joesten, J. F. Rusling, S. L. Suib, “Controlling the Active Sites of Sulfur-Doped Carbon Nanotube–Graphene Nanolobes for Highly Efficient Oxygen Evolution and Reduction Catalysis”, Advanced Energy Materials, 6, 150196 (2016).
[115] S. Yagi, Y. Menjo, C. Tsukada, S. Ogawa, G. Kutluk, H. Namatame, M. Taniguchi, “Vulcanization reaction of squalene and S8powder studied by Sulfur K-edge NEXAFS under liquid phase”, IOP Conference Seriers: Materials Science and Engineering, 76, 012004 (2015).
[116] B. Lassalle-Kaiser, D. Merki, H. Vrubel, S. Gul, V. K. Yachandra, X. Hu, J. Yano, “Evidence from in Situ X-ray Absorption Spectroscopy for the Involvement of Terminal Disulfide in the Reduction of Protons by an Amorphous Molybdenum Sulfide Electrocatalyst”, Journal of The American Chemical Society, 137, 314-321 (2015).
[117] V. R. Surisetty, Y. Hu, A. K. Dalai, J. Kozinski, “Structural characterization and catalytic performance of alkali (K) and metal (Co and Rh)-promoted MoS2 catalysts for higher alcohols synthesis”, Applied Catalysis A, 392, 166-172 (2011).
[118] J. X. Song, T. Xu, M. L. Gordin, P. Y. Zhu, D. P. Lv, Y. B. Jiang, Y. S. Chen, Y. H. Duan, D. H. Wang, “Nitrogen-Doped Mesoporous Carbon Promoted Chemical Adsorption of Sulfur and Fabrication of High-Areal-Capacity Sulfur Cathode with Exceptional Cycling Stability for Lithium-Sulfur Batteries”, Advanced Functional Materials, 24, 1243-1250 (2014).
[119] P. Y. Zhu, J. X. Song, D. P. Lv, D. H. Wang, C. Jaye, D. A. Fischer, T. P. Wu, Y. S. Chen, “Mechanism of Enhanced Carbon Cathode Performance by Nitrogen Doping in Lithium–Sulfur Battery: An X-ray Absorption Spectroscopic Study”, The Journal of Physical Chemistry C, 118, 7765-7771 (2014).
[120] Y. Gorlin, A. Siebel, M. Piana, T. Huthwelker, H. Jha, G. Monsch, F. Kraus, H. A. Gasteiger, M. Tromp, “Operando Characterization of Intermediates Produced in a Lithium-Sulfur Battery”, Journal of The Electrochemical Society, 162, A1146-A1155 (2015).
[121] I. Persson, E. Damian Risberg, P. D′Angelo, S. De Panfilis, M. Sandström, A. Abbasi, “X-ray Absorption Fine Structure Spectroscopic Studies of Octakis(DMSO)lanthanoid(III) Complexes in Solution and in the Solid Iodides”, Inorganic Chemistry, 46, 7742-7748 (2007).
[122] K. Peng, H. J. Wang, H. F. Gao, P. F. Wan, M. B. Ma, X. Y. Li, “Emerging hierarchical ternary 2D nanocomposites constructed from montmorillonite, graphene and MoS2 for enhanced electrochemical hydrogen evolution”, Chemical Engineering Journal, 393, 124704 (2020).
[123] S. Stambula, N. Gauquelin, M. Bugnet, S. Gorantla, S. Turner, S. H. Sun, J. Liu, G. X. Zhang, X. L. Sun, G. A. Botton, “Chemical Structure of Nitrogen-Doped Graphene with Single Platinum Atoms and Atomic Clusters as a Platform for the PEMFC Electrode”, The Journal of Physical Chemistry C, 118, 3890-3900 (2014).
[124] R. J. Nicholls, A. T. Murdock, J. Tsang, J. Britton, T. J. Pennycook, A. Koos, P. D. Nellist, N. Grobert, J. R. Yates, “Probing the Bonding in Nitrogen-Doped Graphene Using Electron Energy Loss Spectroscopy”, ACS Nano, 7, 7145-7150 (2013).
[125] J. Gao, Y. Wang, H. H. Wu, X. Liu, L. L. Wang, Q. L. Yu, A. W. Li, H. Wang, C. Q. Song, Z. R. Gao, M. Peng, M. T. Zhang, N. Ma, J. O. Wang, W. Zhou, G. X. Wang, Z. Yin, D. Ma, “Construction of a sp3/sp2 Carbon Interface in 3D N-Doped Nanocarbons for the Oxygen Reduction Reaction”, Angewandte Chemie International Edition, 58, 15089-15097 (2019).
[126] S. H. AlMarzooqi, M. S. Katsiotis, S. M. Alhassan, “Hybrid Porous Molybdenum Disulfide Monolith for Liquid Removal of Dibenzothiophene”, Industrial & Engineering Chemistry Research, 56, 15049-15057 (2017).
[127] J. Ekspong, T. Sharifi, A. Shchukarev, A. Klechikov, T. Wågberg, E. Gracia-Espino, “Stabilizing Active Edge Sites in Semicrystalline Molybdenum Sulfide by Anchorage on Nitrogen-Doped Carbon Nanotubes for Hydrogen Evolution Reaction”, Advanced Functional Materials, 26, 6766-6776 (2016).
[128] Y. G. Li, H. L. Wang, L. M. Xie, Y. Y. Liang, G. S. Hong, H. J. Dai, “MoS2 Nanoparticles Grown on Graphene: An Advanced Catalyst for the Hydrogen Evolution Reaction”, Journal of The American Chemical Society, 133, 7296-7299 (2011).
[129] J. Bonde, P. G. Moses, T. F. Jaramillo, J. K. Norskov, I. Chorkendorff, “Hydrogen evolution on nano-particulate transition metal sulfides”, Faraday Discussions, 140, 219-231 (2008).
[130] D. J. Li, U. N. Maiti, J. Lim, D. S. Choi, W. J. Lee, Y. Oh, G. Y. Lee, S. O. Kim, “Molybdenum Sulfide/N-Doped CNT Forest Hybrid Catalysts for High-Performance Hydrogen Evolution Reaction”, Nano Letters, 14, 1228-1233 (2014).
[131] Z. Zhang, J. Hao, W. Yang, J. Tang, “Defect-Rich CoP/Nitrogen-Doped Carbon Composites Derived from a Metal–Organic Framework: High-Performance Electrocatalysts for the Hydrogen Evolution Reaction”, ChemCatChem, 7, 1920-1925 (2015).
[132] J. G. Li, K. F. Xie, H. C. Sun, Z. S. Li, X. Ao, Z. H. Chen, K. K. Ostrikov, C. D. Wang, W. J. Zhang, “Template-Directed Bifunctional Dodecahedral CoP/CN@MoS2 Electrocatalyst for High Efficient Water Splitting”, ACS Applied Materials & Interfaces, 11, 36649-36657 (2019).
[133] D. M. Nguyen, P. D. H. Anh, L. G. Bach, Q. B. Bui, “Hierarchical heterostructure based on molybdenum dichalcogenide nanosheets assembled nitrogen doped graphene layers for efficient hydrogen evolution reaction”, Materials Research Bulletin, 115, 201-210 (2019).
[134] H. H. Sun, X. Y. Ji, Y. F. Qiu, Y. Y. Zhang, Z. Ma, G. G. Gao, P. A. Hu, “Poor crystalline MoS2 with highly exposed active sites for the improved hydrogen evolution reaction performance”, Journal of Alloys & Compounds, 777, 514-523 (2019).
[135] C. Gennequin, S. Kouassi, L. Tidahy, R. Cousin, J. F. Lamonier, G. Garcon, P. Shirali, F. Cazier, A. Aboukais, S. Siffert, “Co-Mg-Al oxides issued of hydrotalcite precursors for total oxidation of volatile organic compounds Identification and toxicological impact of the by-products”, Comptes Rendus Chimie, 13, 494-501 (2010).
[136] S. S. Zhang, J. Y. Zhu, X. W. Zhang, R. L. Zhu, F. Ge, Y. Xu, “The removal mechanism of nitrobenzene by the Cu-Fe/Carbon material under different aeration conditions”, Journal of Hazardous Materials, 403, 123584 (2021).
[137] L. H. Zhang, F F. Li, D. G. Evans, X. Duan, “Cu-Zn-(Mn)-(Fe)-Al Layered Double Hydroxides and Their Mixed Metal Oxides: Physicochemical and Catalytic Properties in Wet Hydrogen Peroxide Oxidation of Phenol”, Industrial & Engineering Chemistry Research, 49, 5959-5968 (2010).
[138] X. Wu, X. An, X. M. Xie, “Preparation of Ni(HCO3)2 and its catalytic performance in synthesis of benzoin ethyl ether”, Transactions of Nonferrous Metals Society of China, 24, 1440-1445 (2014).
[139] D. Rosu, M. Birzescu, M. S. Milea, M. C. Pascariu, V. Sasca, M. Niculescu, “Synthesis-Structure Relationship in the Aqueous Ethylene Glycol-Iron(Iii) Nitrate System”, Revue Roumaine de Chimie, 59, 789-796 (2014).
[140] L. Chen, S. P. Wang, J. J. Zhou, Y. L. Shen, Y. J. Zhao, X. B. Ma, “Dimethyl carbonate synthesis from carbon dioxide and methanol over CeO2 versus over ZrO2: comparison of mechanisms”, RSC Advances, 4, 30968-30975 (2014).
[141] S. Y. Gong, X. F. Wu, J. L. Zhang, N. Han, Y. F. Chen, Facile solution synthesis of Cu2O-CuO-Cu(OH)2 hierarchical nanostructures for effective catalytic ozone decomposition”, CrystEngComm, 20, 3096-3104 (2018).
[142] J. Park, K. Lim, R. D. Ramsier, Y. C. Kang, “Spectroscopic and Morphological Investigation of Copper Oxide Thin Films Prepared by Magnetron Sputtering at Various Oxygen Ratios”, Bulletin - Korean Chemical Society, 32, 3395-3399 (2011).
[143] K. R. Aguiar, V V. G. Santos, M. N. Eberlin, K. Rischka, M. Noeske, G. Tremiliosi-Filho, U. P. Rodrigues, “Efficient green synthesis of bis(cyclic carbonate) poly(dimethylsiloxane) derivative using CO2 addition: a novel precursor for synthesis of urethanes”, RSC Advances, 4, 24334-24343 (2014).
[144] V. Bondarenka, V. Jasulaitiene, R. Sereika, A. Stirk, “Sol-gel synthesis and XPS study of vanadium pentoxide xerogels intercalated with glucose”, Journal of Sol-Gel Science and Technology, 71, 385-390 (2014).
[145] D. M. de los Santos, S. Chahid, R. Alcantara, J. Navas, T. Aguilar, J. J. Gallardo, R. Gomez-Villarejo, I. Carrillo-Berdugo, C. Fernandez-Lorenzo, “MoS2/Cu/TiO2 nanoparticles: synthesis, characterization and effect on photocatalytic decomposition of methylene blue in water under visible light”, Water Science & Technology, 184-193 (2018).
[146] Riyanto, M. R. Othman, “Electrosynthesis and Characterization of Cu(OH)2 Nanoparticle using Cu and Cu-PVC Electrodes in Alkaline Solution”, International Journal of Electrochemical Science, 10, 4911-4921 (2015).
[147] D. Li, X. F. Chen, Y. Z. Lv, G. Y. Zhang, Y. Huang, W. Liu, Y. Li, R. S. Chen, C. Nuckolls, H. W. Ni, “An effective hybrid electrocatalyst for the alkaline HER: Highly dispersed Pt sites immobilized by a functionalized NiRu-hydroxide”, Applied Catalalysis B : Environmental, 269, 118824 (2020).
[148] G. B. Chen, T. Wang, J. Zhang, P. Liu, H. J. Sun, X. D. Zhuang, M. W. Chen, X. L. Feng, “Accelerated Hydrogen Evolution Kinetics on NiFe-Layered Double Hydroxide Electrocatalysts by Tailoring Water Dissociation Active Sites”, Advanced Materials, 30, 1706279 (2018).
[149] D. Li, B. W. Zhang, Y. Li, R. S. Chen, S. Hu, H. W. Ni, “Boosting hydrogen evolution activity in alkaline media with dispersed ruthenium clusters in NiCo-layered double hydroxide”, Electrochemistry Communications, 101, 23-27 (2019).
[150] M. Bhavanari, K. R. Lee, C. J. Tseng, I. H. Tang, H. H. Chen, “CuFe electrocatalyst for hydrogen evolution reaction in alkaline electrolysis”, International Journal of Hydrogen Energy, (2021).
[151] E. Ochiai, Chemicals for Life and Living (Springer, Berlin, Heidelberg, 2011), pp. 288.
[152] Z. Y. Kang, G. Q. Yang, J. K. Mo, Y. F. Li, S. L. Yu, D. A. Cullen, S. T. Retterer, T. J. Toops, G. Bender, B. S. Pivovar, J. B. Green, F. Y. Zhang, “Novel thin/tunable gas diffusion electrodes with ultra-low catalyst loading for hydrogen evolution reactions in proton exchange membrane electrolyzer cells”, Nano Energy, 47, 434-441 (2018).
[153] A. I. Inamdar, H. S. Chavan, B. Hou, C. H. Lee, S. U. Lee, S. Cha, H. Kim, H. Im, “A Robust Nonprecious CuFe Composite as a Highly Efficient Bifunctional Catalyst for Overall Electrochemical Water Splitting”, Small, 16, 1905884 (2020). |